CN1914869A - System for processing data unit of radio protocol layer - Google Patents

Abstract

The present invention relates to a system for processing data units of a radio protocol layer. A reordering buffer for reordering data blocks is provided for each logical channel. Unnecessary data transmission delay is prevented and transmission efficiency at a radio interface is enhanced because the present invention is directed to reordering data units of a MAC-d SDU or MAC-d PDU, compared to the conventional art in which the reordering operation is performed according to the units of a MAC-e PDU.

Description

Be used to handle the system of the data cell of radio protocol layer

Technical field

The present invention relates to media interviews control (MAC) layer of mobile communication system, and more specifically say the system that relates to the data cell that is used to handle radio protocol layer.

Background technology

Though developed mobile communication system significantly for the high capacity data communication service, the performance of mobile communication system can not be mated existing wired communication system.Therefore, in a plurality of companies and tissue, carry out technological development, and actively carry out the standardization of this technology as the IMT-2000 of the communication system that allows high capacity data to communicate by letter.

As the Universal Mobile Telecommunications System (UMTS) of the IMT-2000 system of European type is that its purpose is to provide the improved mobile communication service based on GSM core network and Wideband Code Division Multiple Access (WCDMA) (W-CDMA) wireless connect technology from the European standard that is known as global system for mobile communications (GSM) 3-G (Generation Three mobile communication system) of coming that develops.

In December, 1998, the ETSI in Europe, the ARIB/TTC of Japan, the T1 of the U.S. and the TTA of Korea S have formed third generation partnership projects (3GPP), and it has created the closed specification of UMTS technology.

In 3GPP, in order to realize the quick of UMTS and otherwise effective technique exploitation, by considering the autonomous behavior of network element and work thereof, for five technical specification group (TSG) have been created in the standardization of carrying out UMTS.

Standard criterion in each TSG exploitation, approval and the management relevant range.In these groups, Radio Access Network (RAN) group (TSG-RAN) exploitation is used for the standard of function, demand and the interface of UMTS grounding wireless access network network (UTRAN) (it is the new Radio Access Network that is used for supporting at UMTS the W-CDMA access technology).

Fig. 1 has illustrated the exemplary basic structure of general UMTS network.As shown in Figure 1, UMTS roughly is divided into terminal or subscriber equipment (UE), UTRAN and core network (CN).

UTRAN comprises one or more RNSs (RNS), and each RNS comprises a radio network controller (RNC) and a plurality of base station (below be called " Node B ").Each Node B comprises one or more sub-districts.

Fig. 2 has illustrated the structure that is used in the Radio interface protocols among the UMTS.In radio protocol layer, terminal and UTRAN exist in pairs, and handle the transfer of data of wave point.Protocol layer among Fig. 2 can be divided into ground floor (L1), the second layer (L2) and the 3rd layer (L3) by following three layers of (OSI) master pattern that interconnects based on development system.Will be described below each radio protocol layer of Fig. 2.

At first, ground floor (L1), that is, physical layer provides data to wave point by using multiple Radio Transmission Technology.Physical layer connects the upper strata that is called as media interviews controls (MAC) layer through transmission channel.Whether shared channel is divided into dedicated transmission channel and Common transport channel to transmission channel by basis.

The second layer (L2) comprises the MAC layer, Radio Link control (RLC) layer, broadcasting/multiple access communication control (BMC) layer and packet data convergence protocol (PDCP) layer.

The MAC layer shines upon multiple logic channel to multiple transmission channel, and it is multiplexed also to carry out the logic channel that is used to shine upon several logic channels to a transmission channel.The MAC layer connects the upper strata that is called as Radio Link control (RLC) layer through logic channel.According to the type of the information that sends, logic channel is divided into the control channel of the information that is used to send control plane and is used to send the traffic channel of the information of user plane.

According to the type of the transmission channel of managing, the MAC layer can be divided into the MAC-b sublayer, MAC-d sublayer, MAC-c/sh sublayer, MAC-hs sublayer and MAC-e sublayer.

The management of MAC-b sublayer is as the BCH (broadcast channel) of the transmission channel of the broadcasting of system information.

The Common transport channel that the management of MAC-c/sh sublayer is shared by a plurality of terminals is such as forward access channel (FACH) or downlink sharied signal channel (DSCH).

The management of MAC-d sublayer is as the dedicated channel (DCH) that is used for the dedicated transmission channel of particular terminal.

In order to support high speed data transfer through up link and down link, the management of MAC-hs sublayer is as the HS-DSCH (high-speed downlink shared channel) of the transmission channel that is used for the high rate downlink data transmission, and the management of MAC-e sublayer is as the E-DCH (enhancing dedicated channel) that is used for the transmission channel of downlink data transmission of high speed.

The basic function of rlc layer is the service quality (QoS) that guarantees each RB (radio bearer) and their corresponding transfer of data.Rlc layer is provided for the independent RLC entity of each RB, with the specific QoS of assurance RB, and provides three RLC patterns, that is, transparent mode (TM), unacknowledged mode (UM) and affirmation mode (AM) are to support multiple QoS type.

RLC also controls the size of the data that are suitable for being sent to wave point, carries out segmentation and cascade function for this wave point RLC in the data that transmit from the upper strata.

PDCP (packet data convergence protocol) layer as the high level of rlc layer allows to be sent effectively on wave point with relatively little bandwidth through the data that the IP grouping such as IPv4 or IPv6 sends.For realizing this, the PDCP layer is carried out header compression function, only makes that the header portion as data sends the information that needs, to increase the efficiency of transmission of wave point.Header-compressed is the basic function of PDCP layer, so the PDCP layer only exists in the PS territory.In order to promote that there is a PDCP entity in every RB about effective header compression function of each PS service.

In addition, the BMC layer is positioned at the top part of rlc layer, its dispatching cell broadcast, and be broadcast to the terminal that is arranged in specific cell.

There is Radio Resource control (RRC) layer in lowermost portion at the L3 layer.Only in control plane, define rrc layer, and its foundation, reconfigure and discharge first and second layers parameter of control about radio bearer, and also control logic channel, transmission channel and physical channel.First and second layers of logical path that provides by wireless protocols are provided RB, are used for the transfer of data between terminal and UTRAN.Generally speaking, the foundation of RB refers to the regulation protocol layer and the characteristic of the required channel of specific data services is provided and each concrete parameter and method of work is set.

To describe HSUPA (High Speed Uplink Packet visit) now in detail.HSUPA allows terminal (UE) to send data to the system of UTRAN with high speed through up link.HSUPA adopt to strengthen the dedicated channel (DCH) that dedicated channel (E-DCH) replaces prior art, and also uses the required HARQ of high-speed transfer (hybrid ARQ) and AMC (adaptive modulation and coding) and such as the technology of the controlled scheduling of Node B.

For HSUPA, Node B sends the down link control information of the E-DCH transmission that is used for control terminal to terminal.Down link control information comprises the response message (ACK/NACK) that is used for HARQ, the channel quality information that is used for AMC, the E-DCH transmission rate allocation information that is used for the controlled scheduling of Node B, E-DCH transmission time started and Transmission Time Interval assignment information, and transport block size information.

Terminal sends uplink control information to Node B.Uplink control information comprises the E-DCH transmission rate request information that is used for the controlled scheduling of Node B, UE buffer status information and UE power state information.Through physical control channel, send up link and the down link control information that is used for HSUPA such as E-DPCCH (enhancing Dedicated Physical Control Channel).

For HSUPA, definition MAC-d stream between MAC-d and MAC-e.In this situation, to be mapped to MAC-d stream such as the dedicated logical channel of DCCH (Dedicated Control Channel) or DTCH (dedicated traffic), MAC-d stream is mapped to transmission channel E-DCII, and transmission channel E-DCII is mapped to physical channel E-DPDCH (enhancing Dedicated Physical Data Channel).Dedicated logical channel can be mapped directly into transmission channel DCH, and in this situation, DCH is mapped to physical channel DPDCH (Dedicated Physical Data Channel).This interchannel mapping relations as shown in Figure 3.

Will be discussed in more detail below the MAC-d sublayer.Emitting side MAC-d sublayer is from from the upper strata (promptly, rlc layer) the MAC-d SDU that receives forms MAC-d PDU (protocol Data Unit), and receiving layer MAC-d sublayer is from the MAC-d PDU that receives from the lower floor MAC-d SDU that reorders, and passes and send them to rlc layer (that is upper strata).The MAC-d sublayer exchanges MAC-d PDU by MAC-d stream and MAC-e sublayer, or through DCH and physical layer exchange MAC-d PDU.The MAC-d sublayer is carried out and is used for optionally switching switching such as transmission channel kinds of transmission channel according to data volume, encrypt or deciphering MAC-d PDU, selection is suitable for the transformat combination (TFC) of channel condition and is used for the function of the C/T multiplexer (CT Mux) of management logic Channel Identifier (C/T) (it identifies each dedicated logical channel when being used for being mapped to a DCH or MAC-d stream at multiplexed several logic channels and with it).Only when the multiplexing logic channel, use C/T field, and the header that this C/T field is added to each MAC-d SDU is to form MAC-d PDU such as logical channel identifier.Current, definition C/T field has 4 bits, and therefore, the maximum number that can be multiplexed to the logic channel of a DCH or a MAC-d stream is 16.Terminal, special, be used for HSUPA the MAC-d sublayer emitting side structure as shown in Figure 4, and the MAC-d form when the multiplexing logic channel is as shown in Figure 5.

The MAC-dPDU of emitting side MAC-e sublayer from receiving from the MAC-d sublayer through MAC-d stream, special, MAC-e SDU forms MAC-e PDU, and receiver side MAC-e sublayer is from from lower floor, especially, the MAC-e PDU that physical layer the receives MAC-e SDU that reorders, and pass and send them to the upper strata.The MAC-e sublayer is through transmission channel E-DCII and physical layer exchange MAC-ePDU.

The MAC-e sublayer belongs to emitting side according to it or receiver side is carried out difference in functionality.At first, carry out according to uplink/downlink control information schedule data transmission and according to the function of the processed data of data emitting side MAC-e sublayer, hybrid ARQ is to send the function of data at a high speed reliably and to carry out the function that TFRC (transformat and combination of resources) selects to be suitable for selection the transformat of channel condition and combination of resources selection.

Specifically, scheduling/priority treatment piece also is used to form the MAC-e PDU that is sent to physical channel.Especially, scheduling/priority treatment piece is according to their length, level flows MAC-d PDU or the MAC-e PDU that receives from the MAC-d sublayer through a MAC-d during being associated in definite Transmission Time Interval (TTI), add length information to the MAC-e header, the 3 bit PID (preferential ID) that the transmission sequence number (TSN) and adding of adding 6 bits of the transmission block be sent to header is used to identify the priority of MAC-d stream and logic channel arrive header.In addition, scheduling/priority treatment piece adds 1 bit version sign (VF) to header, forming MAC-ePDU, thereby after support different MAC-e PDU forms.

The structure of emitting side MAC-e sublayer and MAC-e PDU form are shown in Fig. 6 and 7.

Generally speaking, reason that use to determine the PDU form of type is receiver side receives () data for example, 0,1,0,1, so uncertain form, receiver side can not explain what each bit represents as a series of bit streams.In HSUPA, use MAC-ePDU form as shown in Figure 7 to have some restrictions as described below.

At first, during a TTI, only send a MAC-e PDU.Therefore, add TSN to each MAC-e PDU.

The second, one MAC-e PDU only comprises and belongs to identical MAC-d stream and have the data of the logic channel of equal priority.Therefore, PID is interpreted as MAC-d stream ID and bgical channel priority.

The 3rd, with data multiplex to a MAC-e PDU of several logic channels, to obtain multiplexed gain.Generally speaking, the length of SDU can be for each logic channel difference, so will indicate the information of the length of each SDU to add header to.

In above-mentioned situation, the length of the header of MAC-e PDU is according to the 3rd condition and difference.The length information of SDU comprises three fields: 3 bit SID (size index) fields that are used to indicate the length of each SDU, be used to indicate the SDU with SID length number 7 bit N fields and to be used to indicate next field be 1 bit F (sign) field of SID length information or MAC-e PDU.Especially, the length information of SDU comprises three fields of SID, N and F, and its size (length) increases with the numbering corresponding to the length type of SDU.

For the PDU that determines through the physical channel wireless transmission, PDU must have and is used for coding, such as the length of determining of modulation of carrying out in physical channel and expansion.Therefore, the MAC-e sublayer produces the PDU that is suitable for the required size of physical channel by the end of filling PDU.This filling part is used to adjust the size of PDU, and does not comprise any information, so when receiver side received PDU, it abandoned filling part.

Receiver side is explained the bit stream that receives according to form as shown in Figure 7.Especially, receiver side is explained from VF (1 bit), PID (3 bit), and TSN (6 bit), SID (3 bit), N (7 bit), the bit stream of F (1 bit) beginning, and explain that header is SDU up to the next part of F field indication.When the next part of F field indication was SDU, receiver side is according to the length information of SDU, and was special, decomposed SDU according to length and number from the SDU of the combination of SID, N and F, from next bit.After extracting SDU, abandon remainder as filling part.

If MAC-e SDU has equal length, the length information of a SDU can be used in the length of other SDU of indication, although use several logic channels to be used to send data.By with reference to figure 7, the one SDU length information, especially, the data length of first logic channel (C/T=1) and second logic channel (C/T=2) is indicated in the combination of SID1, N1 and F1, and K SDU length information, especially, SIDK, the data length of the 4th logic channel (C/T=4) to k logic channel (C/T=k) indicated in the combination of NK and FK.Especially, MAC-e can't help the sublayer logic channel deal with data, but according to the big or small deal with data of MAC-e SDU.

The structure of receiver side MAC-e sublayer as shown in Figure 8.The HARQ piece of receiver side is corresponding to the HARQ piece of emitting side, and the HARQ of each HARQ piece handles with emitting side and carries out SAW (stop and waiting for) ARQ function.When receiver side when HARQ handle to receive a MAC-e PDU, its VF of header that reads MAC-e PDU is to check version and to check PDU that next PID field receives with identification is corresponding to which MAC-d stream and which priority.Divide this operation of execution in the cloth in reorder queue, and transmit PDU afterwards to the piece that reorders by the PID indication.

The reordering function of receiver side is compared the noticeable place of emitting side and is the MAC-e sublayer by the out-of-sequence reception of HARQ MAC-e PDU, but rlc layer is special, and the upper strata after the MAC-d sublayer needs to transmit in turn.Therefore, the MAC-e PDU that non-order receives that reorders the sublayer, and order transmits them to the upper strata.For execution is reordered, each PID has the buffer of reordering, though and can successfully receive definite PDU, if TSN is not an order, interim storage PDU in buffer, and, send it to the upper strata when the transmission in turn of PDU when being possible.Except the VF and the PID of the header of PDU, the part of storage TSN in the buffer that reorders, and when transmitting PDU to block of decomposition is decomposed SDU, and is sent to the MAC-d sublayer on top afterwards under the situation of the SDU length information of inspection SID, N and F.Especially, only transmit MAC-e SDU or MAC-d PDU by MAC-d stream.

In HSUPA, the similar of the MAC-d sublayer of the UTRAN of receiver side is in the MAC-d sublayer of the terminal of emitting side.Especially, carry out the function of emitting side about the part of HSUPA, but with opposite order.For the work about DCH, only difference is that terminal execution TFC selects, and UTRAN operation dispatching/priority treatment.

In HSUPA, the C/T multiplexer block reads the MAC-d PDU that receives from the MAC-e sublayer by MAC-d stream, belongs to which logic channel to detect data (MAC-d PDU just), remove the C/T field, extract MAC-d SDU and send them to the top rlc layer via the channel biography that the C/T field is indicated.But, only when the multiplexing logic channel, have the C/T field.If multichannel multiplexes logical channels not, the MAC-d PDU of reception is MAC-d SDU, sends them to rlc layer so the C/T multiplexer block directly passes.

Fig. 9 shows the structure of the MAC-d sublayer of UTRAN among the HSUPA.Receiver side MAC-e has the buffer that reorders that is used for each PID.When receiving MAC-e PDU, MAC-e is by using the pid information that comprises to select to be used to the buffer that reorders of the data that transmit reception in the MAC-e PDU that receives, determine by the TSN information that use comprises MAC-e PDU must be arranged in selected which position of buffer of reordering in the MAC-e PDU that receives, and aligned data.In the buffer that reorders, all MAC-e PDU that will have less than the TSN value of the TSN value of the MAC-e PDU that receives are delivered to the higher level, and the MAC-ePDU of reception is delivered to the higher level.

But, in the prior art, the degradation in efficiency of transfer of data, and at the unnecessary memory of receiver side needs.For example, suppose that existence is from the MAC-e PDU of emitting side transmission and the MAC-e PDU that accumulates the buffer that reorders at receiver side, as shown in figure 10 after arriving.For the cause of explaining, only the content about MAC-e PDU header illustrates TSN, and supposition MAC-e PDU has identical PID.In addition, also suppose the normal MAC-e PDU that receives and handle up to MAC-e PDU with TSN=3.

Figure 10 has illustrated the structure of the MAC-e PDU that transmits and receives between emitting side and receiver side.Emitting side sends the MAC-e PDU from TSN=5 to TSN=7, and receiver side receives the MAC-e PDU from TSN=5 to TSN=7.Even received corresponding to TSN=5 to the MAC-e PDU of TSN=7, because do not receive the MAC-ePDU with TSN=4 at receiver side, the MAC-e PDU in the buffer that reorders from TSN=4 to TSN=7 waits for and not processed.

As shown in figure 10, also there is not the MAC-e PDU of the received TSN=4 of having only to comprise MAC-d SDU at the buffer that reorders corresponding to logic channel 1.Especially, the MAC-e PDU with TSN=4 does not comprise the MAC-d SDU corresponding to logic channel 2.Therefore, the MAC-d SDU corresponding to logic channel 2 that comprises in the MAC-e PDU from TSN=5 to TSN=7 can be sent to the higher level immediately.

But, in the prior art, the MAC-d SDU that comprises among the MAC-e PDU from TSN=5 to TSN=7 corresponding to logic channel 2 stay in the buffer that reorders and by with MAC-e PDU separately, and be not sent to the higher level, cause unwanted transmission delay thus.Especially, if be used for real-time stream or the voice service that sends corresponding to the data of logic channel 2, problem is more serious.

Summary of the invention

Technical problem

The present invention relates to handle the system of the data cell of radio protocol layer.

Technical scheme

Other advantage of the present invention, purpose and feature will partly be described in explanation subsequently, and through following check or study from the practice of the present invention, above-mentioned advantage, purpose and feature are conspicuous for the person of ordinary skill of the art.Objects and advantages of the present invention can realize and obtain as specifically noted in appended specification and claims and the accompanying drawing.

For realizing these and other advantage of the present invention, and according to purpose of the present invention, as describing particularly and widely here, the present invention is embodied in a kind of method that is used for handling in communication system grouped data, this method comprises: from each at least one data unit of reception of a plurality of logic channels, structure comprises from the data block of at least one data cell of each of a plurality of logic channels and distributing serial numbers gives data block, send data block, receive and process data block makes each at least one data cell from a plurality of logic channels be forwarded to be used for a plurality of logic channels the buffer and transmit each that arrives a plurality of logic channels at least one data unit according to sequence number of reordering of each.

Preferably, treatment step comprises data block is decomposed at least one data cell from each of a plurality of logic channels.Transfer step comprises at least one data cell that determines whether to receive in proper order from each of a plurality of logic channels.

In one aspect of the invention, if definite at least one data cell that sequentially receives from particular logical channel transmits data cell to corresponding logic channel.If determine to receive at least one data cell out-of-sequencely from particular logical channel, with any other data cell of in the buffer that reorders, storing this data cell that reorders, and determine whether the data cell that reorders is in the suitable order that is used to be sent to respective logical channels.

In another aspect of this invention, the step that receives and transmit is carried out in media interviews controls (MAC) layer.

In another embodiment of the present invention, be used for comprising in the method for communication system processing grouped data: reception comprises from least one data cell of each of a plurality of logic channels and has the data block of the sequence number of distribution, the buffer that reorders of each that process data block makes at least one data cell from each of a plurality of logic channels be forwarded to be used for a plurality of logic channels, and transmit at least one data unit to each of a plurality of logic channels according to sequence number.

Preferably, treatment step comprises data block is decomposed at least one data cell from each of a plurality of logic channels.Transfer step comprises at least one data cell that determines whether sequentially to receive from each of a plurality of logic channels.

In one aspect of the invention, if definite at least one data cell that sequentially receives from particular logical channel transmits data cell to corresponding logic channel.If determine to receive at least one data cell out-of-sequencely from particular logical channel, with any other data cell of in the buffer that reorders, storing this data cell that reorders, and determine whether the data cell that reorders is in the suitable order that is used to be sent to respective logical channels.

In another aspect of this invention, the step that receives and transmit is carried out in media interviews controls (MAC) layer.

In another embodiment of the present invention, be used for comprising: portable terminal in the system of communication system processing grouped data, it is used for each at least one the data unit of reception from a plurality of logic channels, structure comprises from the data block of at least one data cell of each of a plurality of logic channels and distributing serial numbers gives data block, and sends data block.

This system further comprises network, it is used to receive makes with process data block and will be forwarded to each the buffer that reorders that is used for a plurality of logic channels from each at least one data cell of a plurality of logic channels, and transmits at least one data unit to each of a plurality of logic channels according to sequence number.

Preferably, network is suitable for coming process data block by data block being decomposed into from each at least one data cell of a plurality of logic channels.Network is suitable for transmitting at least one data unit by each at least one data cell that determines whether sequentially to receive from a plurality of logic channels.

In one aspect of the invention, if definite at least one data cell that sequentially receives from particular logical channel transmits data cell to corresponding logic channel.If determine to receive at least one data cell out-of-sequencely from particular logical channel, with any other data cell of in the buffer that reorders, storing this data cell that reorders, and determine whether the data cell that reorders is in the suitable order that is used to be sent to respective logical channels.

In another aspect of this invention, the reception of network and transmitting function are carried out in media interviews controls (MAC) layer.

In another embodiment of the present invention, the network that is used for handling in communication system grouped data comprises: reflector, and it is suitable for sending data and through the second channel portable terminal that sends control information through first channel; Receiver, it is suitable for receiving information from portable terminal; And controller.This controller be suitable for receiving comprise from a plurality of logic channels each at least one data cell and have the data block of the sequence number of distribution, process data block makes at least one data cell from each of a plurality of logic channels be forwarded to each the buffer and transmit at least one data unit to each of a plurality of logic channels according to sequence number of reordering of a plurality of logic channels.

Preferably, this controller is suitable for coming process data block by data block being decomposed into from each at least one data cell of a plurality of logic channels.This controller is suitable for transmitting at least one data unit by each at least one data cell that determines whether sequentially to receive from a plurality of logic channels.

In one aspect of the invention, if definite at least one data cell that sequentially receives from particular logical channel transmits data cell to corresponding logic channel.If determine to receive at least one data cell out-of-sequencely from particular logical channel, with any other data cell of in the buffer that reorders, storing this data cell that reorders, and determine whether the data cell that reorders is in the suitable order that is used to be sent to respective logical channels.

In another aspect of this invention, controller is suitable in media interviews controls (MAC) layer.

Should be appreciated that aforementioned general description of the present invention and following specific descriptions all are exemplary and explanat, and be intended to provide the present invention's further explanation as claimed in claim.

Description of drawings

Accompanying drawing comprises in order further to understand the present invention, and be included into a part that constitutes this specification in this specification, these accompanying drawings show one or more embodiment of the present invention, and are used for this specification principle of the present invention being described.The feature of in different accompanying drawings, representing of the present invention, element by same numbers with aspect represent, equivalence identical or similarly feature, element or aspect according to one or more embodiment.

Fig. 1 has illustrated the network configuration of existing UMTS.

Fig. 2 has illustrated the structure that is used in the existing wireless protocols among the UMTS;

Fig. 3 has illustrated the MAC layer of existing HSUPA;

Fig. 4 has illustrated the structure of the MAC-d sublayer of existing terminal;

Fig. 5 has illustrated the existing form that is used for the multiplexed MAC-d PDU of logic channel;

Fig. 6 has illustrated the structure of the MAC-e sublayer of existing emitting side;

Fig. 7 has illustrated the form of existing MAC-e PDU;

Fig. 8 has illustrated the structure of the MAC-e sublayer of existing receiver side;

Fig. 9 has illustrated the structure of the MAC-d sublayer of existing UTRAN;

Figure 10 has illustrated existing MAC-e PDU and the example of the buffer that reorders;

Figure 11 has illustrated first embodiment according to existing receiver side MAC-e structure of the present invention;

Figure 12 has illustrated first embodiment according to the MAC-d structure of receiver side of the present invention;

Figure 13 has illustrated first embodiment according to the MAC-e structure of emitting side of the present invention;

Figure 14 has illustrated second embodiment according to the MAC-e structure of emitting side of the present invention;

Figure 15 has illustrated first embodiment according to the MAC-d structure of emitting side of the present invention;

Figure 16 has illustrated the 3rd embodiment according to the MAC-e structure of emitting side of the present invention;

Figure 17 has illustrated second embodiment according to the MAC-e structure of receiver side of the present invention;

Figure 18 has illustrated second embodiment according to the MAC-d structure of receiver side of the present invention;

Figure 19 has illustrated the 4th embodiment according to the MAC-e structure of emitting side of the present invention;

Figure 20 has illustrated the 3rd embodiment according to the MAC-e structure of receiver side of the present invention;

Figure 21 has illustrated first embodiment according to MAC-e PDU of the present invention;

Figure 22 has illustrated second embodiment according to MAC-e PDU of the present invention;

Figure 23 has illustrated the 3rd embodiment according to MAC-e PDU of the present invention;

Figure 24 has illustrated the 4th embodiment according to MAC-e PDU of the present invention;

Figure 25 has illustrated the 5th embodiment according to MAC-e PDU of the present invention;

Figure 26 has illustrated the 6th embodiment according to MAC-e PDU of the present invention;

Figure 27 has illustrated the 7th embodiment according to MAC-e PDU of the present invention;

Figure 28 has illustrated the 8th embodiment according to MAC-e PDU of the present invention;

Figure 29 has illustrated the 9th embodiment according to MAC-e PDU of the present invention;

Figure 30 has illustrated the network that is used for handling in communication system grouped data according to an embodiment of the invention.

Embodiment

With preferred embodiments of the present invention will be described in detail with reference to the annexed drawings.

The present invention relates to be used to handle the system of the data cell of MAC layer, and relate to and compare wherein the prior art of carrying out the operation of reordering according to the unit of MAC-e PDU, the reorder data cell of MAC-dSDU or MAC-d PDU, special, the construction unit of MAC-d SDU.

Basic conception of the present invention is that the every logic channel in the receiver side setting provides the buffer that reorders, make and compare wherein the prior art that in receiver side every PID provides a priority cache device and priority cache device to carry out to reorder and operate that on MAC-e PDU each logic channel buffer that reorders is carried out and reordered on MAC-d SDU.

Preferably, in MAC-d SDU, comprise and be used for the logic channel sequence number that reordering of buffer handle that reorders.

Preferably, being used for the logic channel sequence number that reordering of buffer handle that reorders is to be used for the sequence number of rlc layer or the sequence number that comprises at MAC-d SDU.

It is out-of-sequence that processing or operation refer to data block if reorder, by the information of use such as sequence number, and the data block (MAC-d SDU) that sequentially reorders and receive, and transmit them afterwards to the higher level.

For example, suppose that respectively with sequence number 0,1,2,3,4 create and number five data blocks according to the establishment order.In aspect this, suppose at receiver side that with 0,31,2,4 order receives data block.Because order receives the data block that is numbered " 0 ", receiver side is sent out immediately and is sent them to the higher level.In when receiving data block 3,, hold it in the buffer that reorders because also do not receive data block 1 and 2.Afterwards, when receiving data block 1,, it is delivered to the higher level immediately because data block 1 is data block 0 piece of order afterwards.In addition, when receiving data block 2, it is delivered to the higher level immediately, and, also transmits the data block 3 that remains in the buffer that reorders because all transmitted data block 0,1 and 2.By this way, carry out the operation of reordering and make that sequentially transmitting the data block that receives arrives the higher level out-of-sequencely.

Figure 11 shows first embodiment according to the MAC-e structure of receiver side of the present invention, and Figure 12 shows first embodiment according to the MAC-d structure of receiver side of the present invention.

Unlike wherein reordering buffer with the reorder prior art of operation of execution according to preferentially providing of MAC-e, MAC-e comprises the buffer that reorders according to as shown in figure 12 logic channel.

The operation of MAC-d and MAC-e is described below with reference to Figure 11 and 12.

When the MAC-e of receiver side received MAC-e PDU, it transmitted MAC-e PDU with the block of decomposition corresponding to the priority of the PID that comprises in MAC-e PDU.The MAC-e PDU that block of decomposition decompose to receive to be reconfiguring it in MAC-d PDU, and transmits the MAC-d PDU that reconfigures to MAC-d.Under the situation that receives MAC-d PDU, the MAC-d SDU that MAC-d will comprise in each MAC-d PDU is delivered to each respective logical channels by the C/T field indication that comprises in each MAC-dPDU.Afterwards, each logic channel that exists in each logic channel reorders buffer according to their the sequence number MAC-d SDU that sequentially reorders.

As mentioned above, in the present invention, in reordering buffer, carries out the logic channel that exists for each logic channel the operation of reordering.Buffer is arranged in MAC-d though logic channel reorders, and as shown in figure 12, they may or be arranged in RLC between MAC-d and RLC.And, in MAC-d, the buffer that reorders can be between multiplexed of transmission channel kinds and higher level, to carry out the illustrated processing of reordering, perhaps between multiplexed of C/T multiplexer block that they can be in MAC-d and the transmission channel kinds, with the execution processing of reordering.

Refer back to the structure of MAC-e PDU as shown in figure 10, all MAC-e PDU have the TSN field.The TSN field is according to the preferential required value of operation that reorders of carrying out in the buffer that reorders.Especially, in the prior art,, and carry out the processing of reordering based on the order of identification according to the order of TSN value identification MAC-e PDU.In the present invention, because use the logic channel buffer that reorders to carry out processings of reordering, the buffer that need not reorder in MAC-e is according to preferentially, and do not need among the MAC-e PDU information about transmission sequence.

No matter when in wave point, send MAC-e PDU, comprise that TSN has increased the overhead of MAC-ePDU, and worsened the efficiency of transmission of wave point.Therefore, the present invention has proposed not use the MAC-e structure of TSN in addition.

In not having the structure of TSN, when MAC-e received new MAC-e PDU, MAC-e was delivered to block of decomposition corresponding to the priority of each PID that comprises with MAC-d PDU in MAC-e PDU.Afterwards, block of decomposition reconfigures MAC-d PDU and they is delivered to MAC-d from MAC-e PDU.Under the situation that receives MAC-d PDU, each logic channel of each C/T field indication that the MAC-d SDU that MAC-d will comprise in each MAC-d PDU comprises in being delivered to by MAC-d PDU.Afterwards, the logic channel that exists for each logic channel reorders buffer based on the sequence number that the comprises MAC-d SDU that reorders in the MAC-d SDU that receives.

Figure 13 shows first embodiment according to the MAC-e structure of the emitting side of not using TSN of the present invention.The place that the MAC-e of Figure 13 is different from prior art is that it does not use Priority Queues.Especially, TSN of the prior art is used for determining the priority of a Priority Queues MAC-ePDU.Therefore, in the present invention, do not use TSN to get rid of the order that must determine MAC-dPDU, this causes MAC-e not need Priority Queues.

Therefore, with reference to Figure 13, the MAC-d PDU that MAC-e determines to receive from MAC-d according to their priority is to transmit them to the HARQ entity.The MAC-d PDU structure that has an equal priority by use after the HARQ entity does not have the MAC-e PDU of TSN information, and sends them to wave point.

The invention allows for and be used for optimizing the structure of MAC-e and MAC-d and the structure of the operation of reordering according to each logic channel.For example, with reference to figure 7, the value of the PID of MAC-E PDU is with distinguishing the MAC-dSDU that is delivered to the MAC layer according to priority from the higher level in the prior art, when each MAC-e PDU is sent to wave point, construct each MAC-e PDU, and the priority of the corresponding MAC-e PDU of notice receiver side makes it possible to handle the MAC-e PDU with identical PID at receiver side in each reorders buffer accordingly with MAC-d SDU with equal priority.In aspect this, the MAC-d PDU with C/T field (it has the identical C/T value corresponding to same logical channel) therefore has equal priority.Therefore, in the prior art, can discern the priority of corresponding MAC-d SDU by using the C/T field, but emitting side and receiver side distinguish and handle MAC-e PDU once more according to PID, do not waste thus with needing and handle resource.In addition, in MAC-e PDU, occupy the nearly additional overhead of PID generation of 3 bits, worsen data transmission efficiency thus through wave point.

As proposing in the present invention, buffer is carried out the operation of reordering because the logic channel that exists according to logic channel reorders, and does not need to be used for the buffer that reorders of each priority.Difference is located in reason MAC-d PDU according to priority also not need emitting side.The MAC-e that this means emitting side does not need the precedence partition function.

The present invention has proposed work in addition and has not had the structure of MAC-e and the MAC-d of PID.Especially, the present invention proposes when MAC-e produces MAC-e PDU, and MAC-e handles from the MAC-d PDU of MAC-d reception and do not distinguish them.Especially, MAC-e constructs MAC-dPDU and will not classify from the MAC-d PDU that MAC-d receives, and sends it.

Preferably, before receiving MAC-d PDU from MAC-d, MAC-e can notify priority or the logic channel of each MAC-d PDU of MAC-d reception.In addition, MAC-e can notify the number of the MAC-d PDU of MAC-d reception in addition.

Figure 14 shows according to the present invention, not according to second embodiment of the MAC-e structure of the emitting side of PID or prioritization.

The place that the operation of MAC-e as shown in figure 14 is different from prior art is, when MAC-e produced MAC-e PDU, it was delivered to MAC-e according to the request of MAC-e with the MAC-d PDU that waits for each logic channel from MAC-d request msg and MAC-d.

In addition, MAC-e can check the data volume of accumulating in each logic channel, the priority of each logic channel, the combination of the data that data volume that MAC-e can send or MAC-e can use is with the combination of definite data of using and the data volume of notifying MAC-d to be received by each logic channel.Afterwards, MAC-d receives data according to the request of MAC-e from each logic channel, and it is delivered to MAC-e.Therefore, MAC-e guarantees MAC-e PDU by using the data that receive from MAC-d.

Because PID is not used in MAC-e PDU, MAC-e does not manage Priority Queues or PID.If MAC-e wishes to know the data volume of accumulating in each logic channel, it can be from the higher level or from the direct solicited message of MAC-d.

Data combination refers to the combination of the MAC-e PDU that MAC-e can produce.By each size of dissimilar MAC-d PDU with corresponding to the number designation data combination of each big or small MAC-d PDU of MAC-d PDU.The data combination that can be used by emitting side is variable according to setting up of channel condition and network, and emitting side can be selected one of admissible combination and send it.

The structure of MAC-e as shown in figure 14 has flexibility, this means that MAC-e can or can not use TSN.Especially, in the structure of MAC-e, when the HARQ entity produced MAC-e PDU with the MAC-d PDU that transmits by MAC-d stream, because the interpolation of TSN is invalid as mentioned above, it can or can sequentially not add the TSN value.

In addition, shown in Figure 15 and 16, can design better simply structure, an interface channel wherein only is provided between MAC-d and MAC-e, and not use several MAC-d stream.

Figure 17 shows second embodiment according to the MAC-e structure of receiver side of the present invention, and Figure 18 shows second embodiment according to the MAC-d structure of receiver side of the present invention.

The operation of MAC-e and MAC-d is different from the local as follows of prior art.

The MAC-e PDU that the HARQ entity will success receives is delivered to the decomposition entity immediately, and decomposes MAC-e PDU that entity decomposes reception immediately reconfiguring it in MAC-d PDU, and transmits the MAC-d PDU that reconfigures to MAC-d.Afterwards, the MAC-d PDU that MAC-d decomposes each reception to be extracting MAC-d SDU, and by using MAC-d SDU that each C/T field transmission of comprising among the MAC-d PDU the extracts buffer that reorders to each respective logical channels.

The buffer that reorders that exists for each logic channel is by using the sequence number that the comprises MAC-d SDU that reorders in each MAC-dSDU, and transmits them to the higher level.

Figure 19 shows according to of the present invention, wherein the 4th embodiment of the MAC-e structure of the emitting side that can work more simply of MAC-e.

In the MAC-e structure of as shown in figure 19 emitting side, MAC-e does not receive the data of each logic channel by MAC-d, but directly receives data from each logic channel.

Especially, MAC-e directly checks the data volume of waiting in each logic channel, and determines the combination of the data that MAC-e can send based on the information of the data volume that can send about the spendable data combination of MAC-e or MAC-e.Meet the MAC-d SDU of established data combination to produce MAC-e PDU from each logic channel reception after the MAC-e.In order to distinguish each logic channel, MAC-e forms MAC-d PDU by adding the MAC-d SDU C/T value that receives from each logic channel, to produce MAC-e PDU.The C/T multiplexer block can be in the MAC-e sublayer or between the higher level of MAC-e and MAC-e.

Figure 20 shows the 3rd embodiment according to the MAC-e structure of receiver side of the present invention.

In MAC-e structure as shown in figure 20, the MAC-d SDU of MAC-e is directly transferred to each logic channel, and without MAC-d.Especially, the MAC-e PDU that the HARQ entity will success receives is directly delivered to the decomposition entity, and decompose entity decompose the MAC-ePDU that receives with reconfigure its each in MAC-d PDU, and transmit them to C/T multiplexer entity.Decompose each MAC-d PDU after the C/T multiplexer entity to extract MAC-d SDU and by use MAC-dSDU that the C/T field transmission that comprises extracts the buffer that reorders in each MAC-d PDU to each logic channel.

Under the situation that receives MAC-d SDU, the buffer that reorders that is used for each logic channel is based on each sequence number MAC-d SDU that sequentially reorders, and transmits them to the higher level.C/T multiplexer entity can be arranged in the MAC-e outside and maybe can be used as new entity and add the RLC entity to.

Figure 21 to 29 has illustrated the various embodiments of the structure of MAC-e PDU.To the MAC-e can be used among the present invention and the new MAC-e PDU structure of MAC-d be described with reference to Figure 21 to 29.

Figure 21 shows first embodiment according to MAC-e PDU of the present invention.

The place that MAC-d PDU structure as shown in figure 21 is different from prior art is that it does not have PID and TSN.Because, do not need TSN and pid value by reorder buffer and carry out the operation of reordering of logic channel setting by logic channel.

Figure 22 shows second embodiment according to MAC-e PDU of the present invention, and Figure 23 shows the 3rd embodiment according to MAC-e PDU of the present invention.

The second and the 3rd embodiment that proposes MAC-e PDU structure is to reduce in the MAC-e of Figure 21 PDU structure the number of the C/T field that comprises in each MAC-d PDU.

First to the 3rd embodiment of MAC-e PDU can be used in MAC-e and the MAC-d that does not use TSN and pid information.

Figure 24 shows the 4th embodiment according to MAC-e PDU of the present invention.

The place that the MAC-e PDU of Figure 24 is different from prior art is that it does not have TSN.Because in the present invention, reorder buffer and carry out the operation of reordering by logic channel of setting does not need the TSN value according to logic channel.

Figure 25 shows the 5th embodiment according to MAC-e PDU of the present invention, and Figure 26 shows the 6th embodiment according to MAC-e PDU of the present invention.

The the 5th and the 6th embodiment that proposes MAC-e PDU structure is to reduce the number of the C/T field that comprises among each MAC-d PDU in the MAC-e of Figure 24 PDU structure.

The the 4th to the 6th embodiment of MAC-e PDU structure can be used in MAC-e and the MAC-d that does not use TSN information.

Figure 27 shows the 7th embodiment according to MAC-e PDU of the present invention.

The place that the MAC-e PDU structure of Figure 27 is different from prior art is that it does not have PID.Because in the present invention, reorder buffer and carry out the operation of reordering by logic channel of setting does not need pid value according to logic channel.

Figure 28 shows the 8th embodiment according to MAC-e PDU of the present invention, and Figure 29 shows the 9th embodiment according to MAC-e PDU of the present invention.

The the 8th and the 9th embodiment that proposes MAC-e PDU structure is to reduce the number of the C/T field that comprises among each MAC-d PDU in the MAC-e of Figure 27 PDU structure.

The the 7th to the 9th embodiment of MAC-e PDU structure can be used in MAC-e and the MAC-d that does not use TSN information.

As mentioned above, the system that is used to handle the data cell of radio protocol layer according to the present invention has following advantage.

Because be used for the logic channel of each logic channel buffer MAC-dSDU that reorders that reorders, prevented unwanted data transfer delay, and, can strengthen efficiency of transmission at wave point because MAC-e PDU does not use header.

Figure 30 has illustrated the block diagram of UTRAN520 according to the preferred embodiment of the invention.UTRAN520 comprises one or more RNSs (RNS) 525.Each RNS525 comprises radio network controller (RNC) 523 and a plurality of Node B (base station) 521 of being managed by RNC.RNC523 handles the access point work about core network of wireless resource allocation and management and conduct.In addition, RNC523 is suitable for carrying out method of the present invention.

Node B 521 receives the information that the physical layer by terminal 400 sends by up link, and sends data to terminal by down link.Node B 521 conducts are used for the access point of the UTRAN520 of terminal 400, or as reflector and receiver operation.It will be apparent to those skilled in the art that and to use that for example, processing unit 410 and other data or digital processing device are easily realized mobile communication equipment 400, independently or and external support logic circuit combination.

By using above-mentioned UTRAN, the present invention can be from each at least one data unit of reception of a plurality of logic channels, structure comprises the data block from least one data cell of each of a plurality of logic channels, and distributing serial numbers is given data block, send data block, receive and process data block makes and will be forwarded to each the buffer that reorders that is used for a plurality of logic channels from each at least one data cell of a plurality of logic channels, and transmit each that arrives a plurality of logic channels at least one data unit according to sequence number.

Though described the present invention about mobile communication, the present invention also can be used for using any wireless communication system of mobile device, such as PDA that is equipped with performance for wireless communications and laptop computer.In addition, the use of describing definite term of the present invention should not limit the scope of the present invention to the wireless communication system of determining type, such as UMTS.The present invention also can be applicable to use other wireless communication system of different air interfaces and/or physical layer, for example, and TDMA, CDMA, FDMA, WCDMA etc.

Preferred embodiment can be embodied as use standard program and/or method, equipment or the manufacturing article of engineering to produce software, firmware, hardware or its combination.Here the term of Shi Yonging " manufacturing article " at hardware logic (for example refers to, integrated circuit (IC) chip, field programmable gate array (FPGA), ASIC(Application Specific Integrated Circuit) (ASIC) etc.) or computer-readable medium (for example, magnetic storage medium (for example, hard drive, floppy disk, tape etc.), optical storage (CD-ROM, CD etc.), the code or the logic that realize in easy mistake type and the non-volatile memory apparatus (for example, EEPROM, ROM, PROM, RAM, DRAM, SRAM, firmware, FPGA (Field Programmable Gate Array) etc.).

Code in the computer-readable medium can be by processor access and execution.Wherein realize the code of preferred embodiment can be further by by the transmission medium visit or through network from file server access.In this case, wherein the manufacturing article of code can comprise transmission medium, and such as Network transmission line, wireless transmission medium is by the signal of propagation such as space, radio wave, infrared signal.Certainly, those skilled in the art will also recognize that and to make a lot of modifications to this configuration without departing from the scope of the invention, and the article of making can comprise any information bearing medium of prior art.

Take place with particular order in the logic realization shown in the accompanying drawing of describing specific operation.In other realization, can different order carry out, the logical operation that modification or deletion are determined, and still realize the preferred embodiments of the present invention.In addition, step can be added to above-mentioned logic and realization still according to the invention.

Foregoing embodiment and advantage only are exemplary, are not interpreted as limitation of the present invention.Content of the present disclosure can be applicable to the device of other types.Specification of the present invention is illustrative, does not limit the scope of claims.To one skilled in the art, many replacements, modification and change all are conspicuous.In claims, the sentence that device adds function is intended to comprise the structure of the function that realization described herein quotes.Be not only the equivalent of structure, also comprise the structure of equivalence.

Claims (24)

1. method that is used for handling grouped data in communication system, this method comprises:

Each at least one data unit of reception from a plurality of logic channels;

Structure comprises from the data block of at least one data cell of each of a plurality of logic channels and distributing serial numbers gives data block;

Send data block;

Receive and at least one data cell of feasible each from a plurality of logic channels of process data block is forwarded to each the buffer that reorders that is used for a plurality of logic channels; With

Transmit each that arrives a plurality of logic channels at least one data unit according to sequence number.

2. the method for claim 1, wherein this treatment step comprises data block is decomposed at least one data cell from each of a plurality of logic channels.

3. the method for claim 1, wherein this transfer step comprises at least one data cell that determines whether sequentially to receive from each of a plurality of logic channels.

4. method as claimed in claim 3, wherein, if definite at least one data cell that sequentially receives from particular logical channel transmits data cell to corresponding logic channel.

5. method as claimed in claim 3, wherein, if determine to receive at least one data cell out-of-sequencely from particular logical channel, with any other data cell of in the buffer that reorders, storing data cell that reorders, and determine whether the data cell that reorders is in the suitable order that is used to be sent to respective logical channels.

6. the method for claim 1, wherein the step of this reception and transmission is carried out in media interviews controls (MAC) layer.

7. method that is used for handling grouped data in communication system, this method comprises:

Reception comprises from least one data cell of each of a plurality of logic channels and has the data block of the sequence number of distribution;

The buffer that reorders of each that process data block makes at least one data cell from each of a plurality of logic channels be forwarded to be used for a plurality of logic channels; With

Transmit each that arrives a plurality of logic channels at least one data unit according to sequence number.

8. method as claimed in claim 7, wherein, this treatment step comprises data block is decomposed at least one data cell from each of a plurality of logic channels.

9. method as claimed in claim 7, wherein, this transfer step comprises at least one data cell that determines whether sequentially to receive from each of a plurality of logic channels.

10. method as claimed in claim 7, wherein, if definite at least one data cell that sequentially receives from particular logical channel transmits data cell to corresponding logic channel.

11. method as claimed in claim 10, wherein, if determine to receive at least one data cell out-of-sequencely from particular logical channel, with any other data cell of in the buffer that reorders, storing data cell that reorders, and determine whether the data cell that reorders is in the suitable order that is used to be sent to respective logical channels.

12. method as claimed in claim 7, wherein, this reception and transfer step are carried out in media interviews controls (MAC) layer.

13. a system that is used for handling in communication system grouped data, this system comprises:

Portable terminal, it is used for each at least one the data unit of reception from a plurality of logic channels, and structure comprises from the data block of at least one data cell of each of a plurality of logic channels and distributing serial numbers gives data block, and sends data block; With

Network, it is used to receive makes with process data block and will be forwarded to each the buffer that reorders that is used for a plurality of logic channels from each at least one data cell of a plurality of logic channels, and transmits at least one data unit to each of a plurality of logic channels according to sequence number.

14. system as claimed in claim 13, wherein, this network is suitable for coming process data block by data block being decomposed into from each at least one data cell of a plurality of logic channels.

15. system as claimed in claim 13, wherein, this network is suitable for transmitting at least one data unit by each at least one data cell that determines whether sequentially to receive from a plurality of logic channels.

16. system as claimed in claim 15, wherein, if definite at least one data cell that sequentially receives from particular logical channel transmits data cell to corresponding logic channel.

17. system as claimed in claim 15, wherein, if determine to receive at least one data cell out-of-sequencely from particular logical channel, with any other data cell of in the buffer that reorders, storing data cell that reorders, and determine whether the data cell that reorders is in the suitable order that is used to be sent to respective logical channels.

18. system as claimed in claim 13, wherein, the reception of this network and transmitting function are carried out in media interviews controls (MAC) layer.

19. a network that is used for handling in communication system grouped data, this network comprises:

Reflector, it is suitable for sending data and through the second channel portable terminal that sends control information through first channel;

Receiver, it is suitable for receiving information from portable terminal; With

Controller, it is suitable for:

Reception comprises from least one data cell of each of a plurality of logic channels and has the data block of the sequence number of distribution,

Each that process data block makes at least one data cell from each of a plurality of logic channels be forwarded to be used for a plurality of logic channels reorder buffer and

Transmit each that arrives a plurality of logic channels at least one data unit according to sequence number.

20. system as claimed in claim 19, wherein, this controller is suitable for coming process data block by data block being decomposed into from each at least one data cell of a plurality of logic channels.

21. system as claimed in claim 19, wherein, this controller is suitable for transmitting at least one data unit by each at least one data cell that determines whether sequentially to receive from a plurality of logic channels.

22. system as claimed in claim 21, wherein, if definite at least one data cell that sequentially receives from particular logical channel transmits data cell to corresponding logic channel.

23. system as claimed in claim 21, wherein, if determine to receive at least one data cell out-of-sequencely from particular logical channel, with any other data cell of in the buffer that reorders, storing data cell that reorders, and determine whether the data cell that reorders is in the suitable order that is used to be sent to respective logical channels.

24. system as claimed in claim 19, wherein, this controller is suitable in media interviews controls (MAC) layer.

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